Transforming undergraduate laboratory courses with interlinked real-world challenges.

Undergraduate laboratory course components often provide training in various techniques without connections to an interlinked real-world scenario. This article emphasizes the benefits of longitudinal integration of research techniques to enhance learning and emphasize societal relevance. An example of a biomedical engineering challenge involving a new pandemic is described.

Hydrogel Scaffolds: Towards Restitution of Ischemic Stroke-Injured Brain.

Chronic brain injury following cerebral ischemia is a severe debilitating neurological condition, where clinical intervention is well known to decrease morbidity and mortality. Despite the development of several therapeutic strategies, clinical outcome in the majority of patients could be better improved, since many still face life-long neurological deficits. Among the several strategic options that are currently being pursued, tissue engineering provides much promise for neural tissue salvage and regeneration in brain ischemia. Specifically, hydrogel biomaterials have been utilized to docket biomolecules, adhesion motifs, growth factors, and other proneural cues for stable stem cell encapsulation. Here, we provide an overview of therapeutic applications of hydrogels in stroke treatment. Special focus is given to design considerations for generation of efficient hydrogel systems for neurological applications. Therapeutic applications of hydrogels in stroke as conducive microenvironments for stem cell transplantation and drug delivery have been discussed. Finally, we present our perspectives on clinical translation of hydrogels for neural tissue regeneration.

Fabrication of micropatterned alginate-gelatin and k-carrageenan hydrogels of defined shapes using simple wax mould method as a platform for stem cell/induced Pluripotent Stem Cells (iPSC) culture.

Micropatterning techniques involve soft lithography, which is laborious, expensive and restricted to a narrow spectrum of biomaterials. In this work we report, first time employment of patterned wax moulds for generation of micropatterned alginate-gelatin and κ-carrageenan (κ-CRG) hydrogel systems by a novel, simple and cost effective method. We generated and characterized uniform and reproducible micropatterned hydrogels of varying sizes and shapes such as square projections, square grooves, and circular grids and crisscrossed hillocks. The rheological analysis showed that κ-carrageenan hydrogels had higher gel strength when compared to alginate-gelatin hydrogels. Human Mesenchymal stem cells (hMSCs) and Human Induced Pluripotent Stem Cells (hiPSCs) were found to be cytocompatible with these hydrogels. This micropatterned hydrogel system may have potential application in tissue engineering and also in understanding the basic biology behind the stem cell/iPSC fate.